Methods and compositions for endothelial binding

ABSTRACT

Novel methods and compositions are provided for modulating homing of leukocytes, particularly lympho-cytes, where the compounds are cross-reactive with Neu5Ac2-3Galβ1-X[Fucα1-y]GlcNAc, where one of x and y is three and the other is four. These compounds may be administered to a host associated with inflammation, to avoid the deleterious effects of leukocyte infiltration and for directing molecules to such sites.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 07/721,160, filed Jun. 26, 1991, abandoned which is a continuation-in-part of application Ser. No. 07/688,037, filed Apr. 19, 1991, abandoned which is a continuation-in-part of application Ser. No. 07/614,616, filed Nov. 16, 1990, which is a continuation-in-part application of Ser. No. 07/539,844, filed Jun. 18, 1990, abandoned, which are incorporated herein by reference.

ACKNOWLEDGEMENTS

The inventions claimed in this application may have been supported in part by grants from the NIH. The U.S. Government may have an interest in this application.

INTRODUCTION

1. Technical Field

The field of this invention is the modulation of leukocyte homing to provide therapies for inflammation and other pathogenic conditions associated with leukocyte infiltration into tissue.

2. Background

The bloodstream is the pathway for numerous cells which migrate throughout the body, monitoring conditions. Cells of the lymphoid and myelomonocytic lineages act to identify foreign substances, such as pathogens, aberrant cells, and some compounds, and remove them from the system. These cells have available a large variety of mechanisms for protecting the host from the foreign substance. Many of these mechanisms are highly destructive and result in cytotoxicity of native tissue, inflammation, degradation, and the like. Mechanisms may involve the production of superoxide, secretion of various degradative compounds, such as performs, endocytosis, etc.

While in many situations these protective mechanisms are salutary, in many other situations, they are found to have detrimental effects, involving inflammatory lesions, such as myocarditis, inflammatory bowel disease, psoriasis, allergic contact dermatitis, lichen planus, lymphoid hyperplasia in the skin, inflamed synovia, reperfusion injury, etc. There is, therefore, an interest in being able to modulate the effects of these various monitoring cells.

In recent years, it has been shown that the migrating cells have specific surface membrane proteins associated with their homing or being directed to a particular site. Specialized venules including the high endothelial venules, serve as beacons for these cells, expressing proteins referred to as endothelial leukocyte adhesion molecules and addressing, which bind to the “homing receptors” or adhesion molecule surface membrane proteins of the migrating cells. After binding to the venules, the cells migrate by diapedesis, by mechanisms unknown, to the site of inflammation or injury. Therefore, by interfering with the binding between the endothelial cell and the leukocyte adhesion element, one may hope to reduce the infiltration of migrating cells into the inflamed site to prevent further aggravation of the site.

Relevant Literature

References associated with the characteristics of HECA-452 include Picker et al., J. Immunol. (1990) 145:3247-3255; Raine et al., Clin. Immunol. Immunopathol. (1990) 57:173-187; Jalkanen et al., J. Invest. Dermatol. (1990) 94:786-792; Picker et al., Am. J. Pathol. (1990) 136:1053-1068; VanDinther-Janssen et al., J. Rheumatol. 17:11-17; Jalkanen et al., Int. J. Cancer (1989) 44:777-782; Facchetti et al., Immunol. Lett. (1989) 20:277-281; Seldenrijk et al., Gut (1989) 30:46-491; Kabl et al., J. Clin. Endocrinol. Metab. (1989) 62:744-751; van der Valk et al., Am. J. Surg. Pathol. (1989) 13:97-106; Duijvestijn et al., Am. J. Pathol. (1988) 130:147-155; and Graber et al., J. Immunol. (1990) 145:819-830.

Lowe et al., Cell (1990) 63:475-484; Phillips et al., Science (1990) 250:1130-1132; Walz et al., Science (1990) 250:1132-1135; and Goelz et al., Cell (1990) 63:1349-1356, report a neutrophil carbohydrate ligand for ELAM-1 as NeuAcα2,3-galβ1-4[Fucα1,3]GlcNac, the sialylated-Lewis X antigen, or sialylated lacto-N-fucopentaose III (sLNFIII).

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1 is a graphic depiction of models for sialyl-Le^(a) and sialyl-Le^(x).

SUMMARY OF THE INVENTION

Compositions are provided for modulating the leukocyte binding involving selectins to endothelial cells as sites of leukocyte exit from the blood. The compositions are characterized by binding to the selectin ELAM-1 or other selectin, and are at least in part other than polypeptide and substantially free of the natural polypeptide associated with the homing receptor, e.g., the cutaneous lymphocyte associated antigen or LECAM-1. These compositions find particular use in inhibiting the homing of leukocytes, particularly lymphocytes, to sites of inflammation.

DESCRIPTION OF THE SPECIFIC EMBODIMENTS

Novel methods and compositions are provided for the prophylactic and therapeutic modulation of homing of leukocytes, particularly lymphocytes, to sites of inflammation. The compositions are characterized by binding to an endothelial cell or leukocyte lectin adesion molecules or if the selectin family are cross-reactive with at least one epitope of sialyl-Le^(x), and sialyl-Le^(a), are other than sialyl-Le^(x) and will usually involve at least about three saccharide monomer units.

The active structures of the compositions which find use will be under about 5,000 molecular weight and may be under about 3,000 molecular weight, generally being at least about 800 molecular weight. The compositions themselves may have multiple copies of the active structures, bonded to a common backbone polymeric chain), liposomes, and the like. Any compound which has the above indicated characteristics of cross reactivity in binding to at least one of ELAM-1, LECAM-1, or GMP-140, is other than sialyl-Le^(x) or protein conjugate thereof and is physiologically and pharmacokinetically acceptable may be employed. The compounds may be naturally occurring or synthetic and may be polysaccharides, synthetic organic compounds or the like.

Of particular interest are the sugars sialic acid (neuraminic acid), galactose, fucose, or derivatives thereof, combined to form an oligosaccharide derivative. The sugar monomers may be further derivatized by having up to four, usually not more than three groups bound to carbon, nitrogen or oxygen, which groups may include an additional sugar, such as sialic acid, glucosamine, galactose, glucose, fucose, etc. alkyl groups, such as methyl, ethyl, acyl groups, such as acetyl, etc. and the like. The site of substitution will not interfere with the binding of the compound to its complementary receptor or lectin domain but may provide such advantages as improved pharmacokinetics, stability, ease of synthesis, reduced toxicity, enhanced affinity, and the like.

Leukocytes which may be modulated as to their homing to tissues, where the leukocyte or endothelial cell is expressing the selectin, include neutrophils, T-lymphocytes and B-lymphocytes, platelets, etc. These cells are found to home to a variety of injured, diseased, or otherwise pathogenic states, particularly associated with inflammation. Infiltration of these cells can be associated with such conditions as psoriasis, allergic contact dermatitis, lichen planus, lymphoid hyperplasia in the skin, non-specific chronic dermatitis, pityriasis lichenoids et varioformis acuta, granuloma annular, cutaneous drug eruption, pityriasis rubra pilaris, inflamed synovia, reperfusion injury, or the like.

Sites to which the leukocytes migrate include peripheral lymph nodes, skin, Peyers patches, spleen, mesenteric lymph nodes (mucosal tissue), synovium, and other lymphoid and extralymphoid tissues and sites of inflamation.

ELAM-1 is a vascular selectin. ELAM-1 recruits neutrophils during acute inflammation, but during chronic inflammation is selectively found in skin, binding skin homing lymphocytes, i.e. it doubles as a skin vascular addresin.

GMP-140 is a vascular selectin binding neutrophils and monocytes early in inflammation; it is also expressed on stimulated platelets.

LECAM-1 is a vascular selectin involved in neutrophil, monocyte, etc. extravasation in acute inflammation, and lymphocyte homing to peripheral lymph nodes and some sites of chronic inflammation.

Selectins are defined structurally, being a lectin with the same or similar structural motifs as LECAM-1 (the Mel-14 antigen).

The peripheral lymph node addressin (PLN) is a glycoprotein (carbohydrate ligand) for the lymph node homing receptor (selectin) LECAM-1.

The mucosal addressin is a 60 kD glycoprotein.

Addressins are defined as any tissue specific vascular adhesion molecule involved in lymphocyte homing.

The subject compositions may be prepared in accordance with conventional ways or isolated from a natural source, e.g. milk. Descriptions of the preparations of sialyl-Le^(x), sialyl-Le^(a), the common portions of the two compounds, namely Neu5Ac2,3Galβ1-x[Fucα1-y] GlcNAc, wherein one of x and y is three, and the other is four, and cross-reactive derivatives thereof are illustrated by the synthesis of a variety of sugars which may be found in Paulsen, (1982) Angew. Chem. Int. Ed 94:184; Fugedi et al., (1987) Glycoconjugate J. 4:97 and Okamoto and Goto, (1990) Tetrahedron 46:5835 Kameyama et al. (1991) Carbohydr. Res. 209:C1; Palcic et al., Carbohydr. Res. (1989) 190:1-11.

The compounds of this invention will be other than the naturally occurring Sialyl-Le^(a) or Sialyl-Le^(x) antigens found as polysaccharide markers on human cells. The compounds are characterized by having a structure which comprises or is immunologically cross-reactive with a structure that comprises a fucopyranose and a sialic acid or derivative thereof in a spatial conformation associated with both sialyl-Le^(a) and sialyl-Le^(x). Thus, the two sugars, sialic acid and fucopyranose will be bonded to a chain which permits the sugars to assume the proper orientation and spatial conformation, preferably provides restraint in maintaining such conformation. The backbone chain may be from 20 to 10, usually 3 to 8, preferably 3 to 7, more preferably 5 to 6 atoms, which may be carbon, nitrogen or oxygen, and may involve alicyclic, cyclic, heterocyclic or aromatic units or combinations thereof. Where a sugar is at least a portion of the backbone, desirably the sialic acid group will be present as the non-reducing terminal sugar of a disaccharide, where the other sugar is preferably galactose, and the disaccharide is separated by from about 1 to 4, preferably 1 to 3, particularly 2 atoms, usually carbon and optionally oxygen atoms, from the fucopyranose. The group serving as the separating chain desirably will be conformationally constrained, particularly as a cyclic or heterocyclic group. The group may be substituted with one or more oxy groups.

By conformationally constrained for cyclic groups are intended ranges of from 3 to 7, usually 5 to 6 annular members, or sterically hindered compounds, or other structures where the atoms of the chain are inhibited from free rotation.

The sialyl and fucopyranose groups may be cis or trans, equatorial or polar, in their spatial positions, usually trans.

For the most part, the subject compositions have as their core structure:

Neu5Acα2-3Galβ1-x[Fucα1-y]R

wherein R is glucose or derivative thereof, e.g., glucosamine, N-acetyl glucosamine, etc., where any of the positions of the core structure may be substituted without interfering with the binding to selectins. Sites for substitution include the available positions of galactose, glucose, and fucose, particularly with a sugar e.g. sialic acid, glucosamine, N-acetyl glucosamine, glucose, neuraminic acid, fucose, disaccharides thereof, etc., where the nitrogen atoms may be alkylated or acylated; and the like.

Of particular interest are compounds comprising a cyclic group to which fucose and a disaccharide with neuraminic acid as the non-reducing terminal sugar is bonded, where the fucose and disaccharide are separated by from 2 to 3 atoms, particularly carbon atoms and optimally an oxygen atom. Thus the cyclic compound may be of 5 to 7 annular members, particularly 6 annular members, and may include 1,2-cyclohexanediol, 1,3-cyclohexanediamine, 1,2-cyclohexanolamine, 1,2-cyclopentandiol, 2,3- or 3,4-dihydroxypyran, and the like. The positions may be cis or trans, preferably trans.

For a variety of purposes, the saccharidic compounds may be conjugated to other compounds, such as lipids, detergents, e.g. non-ionic detergents, such as polyalkyleneoxy groups, with alkylene of from 2-3 carbon atoms, usually under about 5 kDal, naturally occurring or synthetic organic compounds where the active structure is under about 2 kDal, which may be alicyclic, aromatic, acyclic or heterocyclic, polymeric compounds, such as physiologically acceptable polymers, e.g. acrylates, proteins, or the like, which may be under about 100 kD or more.

Proteins which may find use as carriers include serum albumin, casein, gelatin, etc. Conjugates may be prepared as immunogens to produce antisera or monoclonal antibodies specific for the binding epitope. Thus, antibodies could be used to inhibit homing of leukocytes, e.g. neutrophils, lymphocytes or other leukocytes. Anti-idiotypic antibodies may be prepared which would compete with the binding epitope for the selectins to prevent lymphocyte infiltration.

The subject compounds may be conjugated to the carriers directly, but more usually through a spacer. Various spacers are known for linking to proteins, particularly spacers incorporating aromatic groups, e.g., phenylene, substituted with from 1 to 2 amino groups where the other functionality may be a carboxylic acid, aldehyde, mercaptan, activated olefin or the like. In bonding the spacer to the saccharide through an amino group, the linkage may provide for retention of the anomeric configuration of the reducing sugars or reductive amination may be employed resulting in an aminoalditol. (Kallin et al. (1986) Glycoconjugate J. 3:311).

Based on the configuration of the binding epitope, using computer assisted design, synthetic organic compounds can be devised which would compete with the binding epitope for the addressin.

The subject compositions may be administered in any convenient way, depending upon the particular nature of the composition. Various physiologically acceptable media may be employed, such as deionized water, saline, phosphate buffered saline, aqueous ethanol, and the like. Depending upon the nature of the compound, it may be administered typically, parenterally or orally, subcutaneously, intravascularly, topically, peritoneally, and the like. The particular dosage will vary with the frequency of administration, the manner of administration, the activity of the compound, the indication being treated, and the like.

The following examples are offered by way of illustration and not by way of limitation.

EXPERIMENTAL MATERIALS

Synthetic glycoproteins (Neoglycoproteins)

The neoglycoproteins used in this paper were produced in BioCarb AB (Lund, Sweden) by chemically coupling 10-20 moles of a specific oligosaccharide to 1 mole of nonglycosylated albumin (bovine or human). The resulting synthetic glycoprotein (neoglycoprotein) contains multiple copies of the identical carbohydrate sequence, thereby producing a well characterized, multivalent glycoconjugate which is extremely effective for studying carbohydrate-protein interactions. Depending on the size of the oligosaccharide, three different chemical spacer arms were used to couple the oligosaccharides to proteins 1) p-aminophenyl (PAP); 2) aminophenylethyl (APE); and 3) acetyl phenylene diamine were used to couple the shorter oligosaccharides to albumin since they will retain the anomeric configuration of the reducing sugars which may be involved in a potential binding site. APD was used to couple the larger sugars to protein by reductive amination, which converts the reducing sugar to an aminoalditol. These reduced sugars are designated by parenthesis in the APD conjugates presented in Table I.

TABLE 1 NAME STRUCTURE LNF I    Fucα1-2Galβ1-3GlcNAcβ1-3Galβ1-4(Glc)  (H-type 2) LNF II                  Galβ1-3G1cNAcβ1-4(Glc) (Le^(a))                            |⁴                            Fucα¹ LNF III           Galβ1-4GlcNAcβ1-3Galβ1-4(Glc) (Le^(X))                     |³                     Fucα¹ sLNFII Neu5Acα2-3Galβ1-3GlcNAcβ1-3Galβ1-4(Glc) (sLe^(a))                     |⁴                     Fucα¹ sLNFIII Neu5Acα2-3Galβ1-4GlcNAcβ1-3Galβ1-4(Glc) (SLe^(X))                     |³                     Fucα¹ LSTa Neu5Acα2-3Galβ1-3GlcNAcβ1-3Galβ1-4(Glc) LSTc Neu5Acα2-6Galβ1-4GlcNAcβ1-3Galβ1-4(Glc) 3′ Sialyllactose               NeuNAc α2-3Gal βl-4 (Glc) 6′ Sialyllactose               NeuNAc α2-6Gal βl-4 (Glc)

Monoclonal Antibodies

The monoclonal antibodies employed include the following. HECA-452, a rat IgM [anti-CLA, (Picker et al. (1990) J. Immunol. 145:3247-3255)] (Duijvestijn et al (1988) Am. J. Path 30:147-155; MECA-79, rat IgM control [anti-peripheral lymph node addressin (Streeter et al. (1988) J. Cell Biol. 107:1853-1862)]; RB6-2C2, rat IgM control [Coffman and Weissman (1981) J. Exp. Med. 153:269]; CL2 (anti-ELAM-1) (Picker et al. (1991), Nature 349:796-799), mouse IgG₁, kindly supplied by C. Wayne Smith (Houston, Tex.); Dreg-56, mouse IgG₁ [anti-human LECAM-1, (Kishimoto et al. (1990) Proc. Nat'l Acad. Sci. USA 87:2244-2248)]; CSLEXI (TT-19, anti-SLNFIII) (Fukushima et al. (1984) Cancer Res. 44:5279-5286), a mouse IgM, kindly given by P. Terasaki (UCLA); and 1H10 (anti-Sialyl Le^(a)) a mouse IgG₁ developed by BioCarb.

Direct Binding of Antibodies to Synthetic Glycoproteins (Neoglycoproteins)

Synthetic glycoproteins were coated onto microtiter plates by filling each well with 100 ng of the neoglycoprotein in 100 μl of 0.15 M sodium chloride, 0.01 M sodium phosphate, 0.1% sodium azide, pH 7.4, (PBS-azide) overnight at 4° C. Standard enzyme-linked immunoassays (ELISA) were then performed on the solid phase carbohydrate structures using the appropriate antibody diluted to 10 μg/ml.

EXAMPLE I

Production of ELAM-1 CDNA Transfected Cell Lines

L1-2/pMRB107 cells (L1-2^(ELAM-1)) were prepared by transfecting the ELAM-1 gene into the murine pre-B cell line L1-2 (Gallatin et al. (1983) Nature 35 304:30-34). A cDNA clone encoding ELAM-1 was obtained from a CDNA library made from activated human umbilical vein endothelial cell cultures by polymerase chain reaction amplification. The ELAM-1 gene was inserted downstream of the hCMV promoter in pMRB101 [a derivative of EE6 which contains the E. coli gpt gene (Mulligan and Berg (1981) Proc. Nat'l. Acad. Sci. USA 78:2072; Stephens and Corbett (1989) N.A.R. 17:7110)]. DNA was introduced into L1-2 cells by electroporation and the cells selected for resistance to mycophenolic acid. A population of cells staining brightly for ELAM-1 were selected by FACS and cloned by limiting dilution. These cells are ELAM-1^(hi) LFA-1^(mod) CD45^(hi) CD44^(neg) LECAM-1^(neg), differing from the parent cell line or control vector transfectants only in their expression of ELAM-1. L1-2/pMRB101 (L1-2^(vector)) cells are a similarly transformed derivative of L1-2 transfected with pMRB101 and lacking ELAM-1 expression.

Cell Binding Assays

One hundred microliter samples of each synthetic glycoconjugate in phosphate buffered saline (PBS), pH 7.2, were absorbed onto glass wells of 8-chamber slides (LabTek) for two hours at RT. For some experiments glass slides were pre-coated with rabbit anti-human serum albumin (Sigma) at 200 μg/ml overnight at 4° C. and washed with PBS prior to the addition of the glycoconjugate. After blocking with 5% NBS/ 10 mM HEPES/Dulbecco's Modified Eagles Medium (DMEM), pH 7.0 (CM), L1-2^(ELAM-1) or L1-2^(vector) cells were applied to each well (1.5×10⁶/0.15 ml in CM). After a 25 minute incubation at RT on a rotating shaker at 50 rpm, the tops of the wells were removed and the slides washed 3× in DMEM and then fixed by incubation in 1.5% glutaral-dehyde (Kodak)/DMEM. Three to six 100× fields were counted for each data point and the average and standard error are reported. Data reported are from representative experiments which were performed 2-5 times with similar results.

Inhibition of Binding of ELAM-1 Containing Cells by Compounds

One hundred and twenty nanograms of Sialyl Le^(a)-HSA or Sialyl Le^(x)-HSA dissolved in 100 μl of phosphate-buffered saline were absorbed per well of an 8 chambered glass (LabTek) slide for 2 hours at room temperature. During this period, L1-2^(ELAM-1) cells were pre-incubated for 20 minutes on ice with increasing concentrations of Sialyl Le^(a)-HSA at 10⁷ cells/ml. After washing and blocking the wells in Complete Medium (CM, 5% normal bovine serum, 10 mM HEPES, pH 7.0, DMEM), L1-2^(ELAM-1) cells pre-incubated with compounds were added (1×10⁷ cells/ml) and incubated at room temperature while rotating at 50 rpm. After 25 minutes, slides were washed 3 times in Dulbeccol's Modified Eagles Medium (DMEM) and then fixed in 1.5% glutaraldehyde/DMEM.

Inhibition of Intercellular Adhesion by Compounds

Normal human neutrophils or peripheral blood mononuclear cells (PBMC) (1-2×10⁶/ml) are incubated in CM for 30 minutes at room temperature while rotating at 50 rpm on a layer of COS cells transfected with ELAM-1 cDNA. After washing, the binding of neutrophils is determined by directly counting the number of neutrophils bound per transfected COS cell. For PBMC, non-adherent cells are removed by washing with DMEM and then adherent cells are removed by washing with a solution of 5 mM EDTA, 5 mM EGTA in PBS. Binding of monocytes is assessed by counting the number of adherent and non-adherent cells and determining the number of monocytes by their distinctive light-scatter profile with FACS analysis and the number of CLA+ lymphocytes by staining with the anti-CLA mAb HECA-452 [Picker, et al. (1991) Nature 349, 796-799]. Neurophils and/or PBMC are pre-incubated with Sialyl-Le^(a)-HSA or other compounds prior to incubation on the layer of ELAM-1 cDNA transfected COS cells. Inhibition of intercellular adhesion is determined as a percentage calculated by:

 number of bound cells in control−number of bound cells in test×100/number of bound cells in control

Binding of Lymphocytes or LECAM-1 CDNA Transfectants to High Endothelial Venules

The interaction of the peripheral lymph node homing receptors (LECAM-1) with high endothelial venules is measured in a frozen section assay in which a suspension of lymphocytes and/or LECAM-1 transfected cell lines are incubated on frozen sections of lymphoid tissues for 20-30 minutes at 7° C. [Stamper and Woodruff (1976) J. of Exp. Med. 144, 828; Butcher, et al., (1980) Eur. J. Immunol. 10, 556] while rotating at 50 rpm. After glutaraldehyde fixation, the number of cells bound per HEV is determined microscopically. Sialyl-Le^(a)-HSA and other compounds are pre-incubated with lymphocytes or transfected cell lines, including LECAM-1 and ELAM-1 transfected L1-2 cells, prior to the assay, and the ability of the compounds to inhibit intercellular adhesion is determined as described above.

Hard Sphere Exo-Anomeric (HSEA) Calculations

Conformational models of the oligosaccharides in solution were obtained by HSEA calculations. Hydroxyl groups are represented by the oxygen atoms. A fixed bond angle of 117° was used for the glycosidic linkages. The energy calculated by an HSEA potential (Bock (1983) Pure Appl. Chem. 55:605-622), was minimized using simultaneous variation of dihedral angles (multi-dimensional binary chop). This algorithm shows a slow convergence near a local minimum when compared to other methods utilizing the first and second derivative, but has the advantage of allowing a large initial search area of the conformational space, whereby the chances of finding the lowest local minima increases. Other applications of this program are described in Kumlien et al. (1989) Arch. Biochem. Biophys. 269:678-689 and Wreslander et al. (1990) Glycoconlugate J. 7:85-100.

RESULTS AND DISCUSSION

Carbohydrate Epitope of Antibody HECA-452

Antibody HECA-452 was tested for direct binding to a wide variety of carbohydrate structures by assaying a panel of neoglycoproteins which were produced by chemically coupling specific oligosaccharides to serum albumin. HECA-452 binds both Sialyl Le^(a) and Sialyl Le^(x) hexasaccharides but not a large variety of other similar but not identical carbohydrate sequences. In comparison, antibody CSLEX-1 which has been reported to bind Sialyl Le^(x) (Fukushima et al. (1984) Cancer Res. 44:5279-86) recognizes an epitope specific to Sialyl Le^(x) and not present in Sialyl Le^(a). Likewise, antibody 1H10, binds to Sialyl Le^(a) but not Sialyl Le^(x). 1H10 also weakly crossreacts with LSTa which is defucosylated Sialyl Le^(a). Titration of the antigens further demonstrates that HECA-452 binds both Sialyl Le^(a) and Sialyl Le^(x) hexasaccharides with similar relative affinities whereas CSLEX-1 and 1H10 maintain specificity to either Sialyl Le^(x) or Sialyl Le^(a) hexasaccharide, respectively.

Carbohydrate Structure Recognized by ELAM-1

The LEC-CAM gene family consists of three membrane bound glycoproteins, ELAM-1, LECAM-1 and GMP-140 (PADGEM, CD62), which have similar domain structures featuring a mammalian C-type lectin domain at their N termini. Several studies confirm that the calcium dependent lectin domains of these molecules are of central importance to their adhesive functions. More recently, the Sialyl Le^(x) antigen has been shown to be a neutrophil ligand for ELAM-1 (Lowe et al. (1990) Cell 63:475-484; Phillips et al. (1990) Science 250:1130-32; and Walz et al. (1990) Science 250:1132-35), and sialic acid moieties perhaps associated with Le^(x) on neutrophils are thought to be important for GMP-140 binding (Larsen et al. (1989) Cell 59:305-12; Moore et al. (1991) J. Cell Biol. 112:491-99; Corral et al. (1990) Biophys. Biochem. Res. Comm. 172:1346-49).

ELAM-1 appears to bind structures other than Sialyl Le^(x). A population of skin-homing memory T lymphocytes, characterized by their expression of a carbohydrate antigen, the cutaneous lymphocyte-associated antigen (CLA) defined by antibody HECA-452, were found to interact specifically with ELAM-1 even though lymphocytes do not express significant levels of Sialyl Le^(x). Furthermore, when isolated from various sources, glycoproteins recognized by the anti-CLA mAb, HECA-452, are adhesive for ELAM-1 cDNA transfectants. Indeed, the association between expression of the HECA-452 epitope and the ability to bind ELAM-1 appeared to be quite close and suggested that ELAM-1 and HECA-452 recognize very similar carbohydrate structures. A sensitive binding assay was developed using cells permanently transfected with ELAM-1 cDNA. The mouse pre-B cell line, L1-2, transfected with ELAM-1 CDNA (L1-2^(ELAM-1)), but not vector control cDNA, L1-₂ ^(vector) expresses very high levels of ELAM-1. The ELAM-1 expressed by these cells is functional as L1-2^(ELAM-1) cells are adhesive for neutrophils and this adhesion is blocked by anti-ELAM-1 monoclonal antibodies. When added to glass slides coated with various synthetic glycoconjugates, L1-2^(ELAM-1) cells bound selectively to Sialyl Le^(a) and Sialyl Le^(x) neoglycoproteins, but not to a number of other glycoconjugates, (see Table I for structures). L1-2^(ELAM-1) cells also bound, albeit more weakly, to Le^(a) neoglycoprotein. The binding to Le^(a) is significant as L1-2^(ELAM-1) cells bound poorly to Le^(x) and not at all to the glycoconjugates prepared with the structural analogs such as LNF I. That L1-2^(ELAM-1) cells did not bind other monosialylated carbohydrates, such as 3′SL, 6′SL, LSTa or LSTc demonstrates that the binding to Sialyl Le^(a) and Sialyl Le^(x) is not due to non-specific charge effects, but rather reflects specific structural features of these oligosaccharides. The results confirm that ELAM-1 and HECA-452 recognize a very similar oligosaccharide domain, presented by both the Sialyl Le^(a) and Sialyl Le^(x) antigens. As shown in Table I, these hexasaccharides have the same sugar composition, but differ sterochemically in that the galactose and the fucose residues are attached to GlcNAc in the 4 and 3 positions respectively in Sialyl Le^(x) (type 2 chain), and in the reverse positions in Sialyl Le^(a) (type 1 chain). The low level of binding of ELAM-1 transfectants to Le^(a) is consistent with an essential role of fucose in recognition but shows that neuraminic acid also plays a key role.

Carbohydrate Structures that Inhibit the Binding of ELAM-1 Dependent Intercellular Adhesion

Sialyl Le^(a)-HSA in solution blocks 100% of binding of ELAM-1 transfected cells (L1-2^(ELAM-1)) to either immobilized Sialyl Le^(x)-HSA or immobilized Sialyl Le^(a)-HSA. As binding to either carbohydrate structure is blocked by Sialyl Le^(a)-HSA, only one carbohydrate-binding site exists in ELAM-1 which recognizes a carbohydrate domain common to both Sialyl Le^(a) and Sialyl Le^(x).

Graphic Representation of the Carbohydrate Epitope for ELAM-1.

The dihedral angles for Sialyl Le^(a) and Sialyl Le^(x) hexasaccharide determined by the HSEA calculations are presented in Table 2. It should be noted that these are theoretical approximations of the native conformation and the disclosure is not restricted to these bond angles. The dihedral angles are specified by the designation of the four atoms defining it. These 4-character designations are made up of the chemical symbol, 2 characters for the number in the monosaccharide (and possible extra specification e.g. to distinguish atoms of the same type bonded to the same carbon), and number of the monosaccharide residue in the oligosaccharide. The last number is defined below:

Dihedral Angle Sialyl-Le^(a)(°) Sialyl-Le^(x)(°) C1 1 - C2 1 - 02 1 - C3 2 188.6240387 189.0001221 C2 1 - 02 1 - C3 2 - H3 2 350.8763428 349.9999695 H1 2 - C1 2 - 01 2 - C* 3 51.3739777 53.2507896 C1 2 - 01 2 - C* 3 - H* 3 15.3727636 8.8746433 H1 3 - C1 3 - 01 3 - C3 4 57.8722878 57.8755035 C1 3 - 01 3 - C3 4 - H3 4 350.6306458 350.6243591 H1 4 - C1 4 - 01 4 - C4 5 55.3822517 55.4999657 C1 4 - 01 4 - C4 5 - H4 5 2.6262217 1.6283444 H1 6 - C1 6 - 01 6 - C# 3 49.7558937 49.8749161 C1 6 - 01 6 - C# 3 - H# 3 18.8635368 23.9994240 09 1 - C9 1 - C8 1 - C7 1 178.1011200 178.2247772 08 1 - C8 1 - C7 1 - C6 1 299.6979065 300.0729675 07 1 - C7 1 - C6 1 - H6 1 180.4196625 182.0449371 06 2 - C6 2 - C5 2 - H5 2 303.0703125 300.8233032 06 3 - C6 3 - C5 3 - H5 3 289.2540588 294.3686523 06 4 - C6 4 - C5 4 - H5 4 306.4527283 306.4491882 06 5 - C6 5 - C5 5 - H5 5 296.1771851 178.0553131 H6A 6 - C6 6 - C5 6 - H5 6 179.6257324 179.8791046 * = 3 in case of Sialyl-Le^(a); 4 in case of Sialyl-Le^(x). # = 4 in case of Sialyl-Le^(a); 3 in case of Sialyl-Le^(x). EMIN (Sialyl-Le^(a)) = −15.7628746 kcal/mol EMIN (Sialyl-Le^(x)) = −14.9528790 kcal/mol

For control purposes the full program output is presented, while the relevant accuracy for comparison with experimental data cannot be expected to be higher than ± for the angles. The error in the HSEA energy value can be expected to lie in the first decimal, when given in kcal/mol. These energy values are of interest when comparing different potential functions etc., but does not lend itself easily to comparison with energies determined from experiments. A large negative value does however show that the attractive van der Waals forces dominate the calculations, giving support for the use of the HSEA approximation (positive energies indicate strong steric forces that may distort bond lengths and angles, which are assumed constant in HSEA). The resulting structures are represented graphically in FIG. 1.

The calculations show high similarity in the corresponding dihedral angles for the two structures, also at the bonds with different linkage between the N-acetyl-glucosamine and the fucose and sialic acid residues, respectively. The different dihedral angles for the hydroxymethyl group in the 6-position of the glucose residue at the reducing terminal (296.2° and 178.1°) is a result of the very nearly equal energies for this molecular group after a rotation of 120°. As this group is far away from the linkages differing between Sialyl Le^(a) and Sialyl Le^(x), its direction is of no importance for the conformational structure in this region. Computer-generated stereo images of the structures are represented graphically in FIG. 1. The conformations indicate that the structures show a high degree of similarity in both the non-reducing and reducing terminal parts, respectively. In particular, the structures of the terminal carbohydrate sequence up to but not including the N-acetyl group on the internal GlcNAc residue, show a high degree of homology and may represent the domain recognized by both ELAM-1 and the monoclonal antibody HECA-452. This area of structural homology is particularly useful for the design of potential anti-inflammatory drugs.

Examples of other carbohydrate-binding proteins that recognize type 1 and type 2 chain isomers are the antibodies E₁23-48 and E₁66-18 which bind the blood group B antigen (Hansson et al. (1983) J. Biol. Chem. 258:4091-97) and the lectin, Griffonia simplicifolia IV, which recognizes both Le^(b) and Le^(y) antigens (Spohr et al. (1985) Can. J. Chem. 63:2644-52).

The recognition of the Sialyl Le^(a) antigen and the Sialyl Le^(x) antigen, by ELAM-1, may be of pathologic importance. Mucins containing these structures are elevated in the sera of cancer patients, including gastrointestinal, pancreatic, and breast cancer patients (Magnani et al. (1982) J. Biol. Chem. 257:14365-369; Magnani et al. (1983) Cancer Res. 43:5481-92). Preliminary experiments indicate that some Sialyl Le^(a) and Sialyl Le^(x)-containing mucins are recognized by ELAM-1 transfectants. By interacting with ELAM-1 on venules in acute and chronically inflamed tissues and interfering with the recruitment of leukocytes to these locations, these mucins secreted by tumors may contribute to the immunodepressed state of cancer patients.

EXAMPLE II

Production of LECAM-1 cDNA transfected cells. A human LECAM-1 cDNA transfected cell line (L1-2^(LECAM-1)) was prepared by transfecting the LECAM-1 gene into the murine pre-B cell line L1-2 (Gallatin et al. (1983) Nature 304:30-34). A cDNA clone encoding LECAM-1 was obtained from a cDNA library made from peripheral blood lymphocytes by polymerase chain reaction amplification. The LECAM-1 gene was inserted downstream of the hCMV promoter in pMRB101 [a derivative of EE6 which contains the E. coli gpt gene (Mulligan & Berg, (1981) Proc. Natl. Acad. Sci. USA 78:2072-2076; Stephens and Cockett, (1989) N.A.R. 7:7110]. DNA was introduced into L1-2 cells by electroporation and the cells selected for resistance to mycophenolic acid. A population of cells staining brightly for LECAM-1 were selected by FACS and cloned by limiting dilution. These cells are LECAM-1^(hi) LFA-1^(mod) CD45^(hi) CD44^(neg), differing from the parent cell line or control vector transfectants only in their expression of LECAM-1. L1-2/PMRB101 (L1-2^(vector)) cells are a similarly transformed derivative of L1-2 transfected with pMRB101 and lack LECAM-1 expression.

Cell binding assays. One hundred microliter samples of each synthetic glycoconjugate in phosphate buffered saline (PBS), pH7.2, were absorbed onto glass wells of 8-chamber slides (LabTek) for two hours at RT. After blocking with 5% NBS, 10 mM HEPES, Dulbecco's Modified Eagles Medium (DMEM), pH7.0 (CM), L1-2^(LECAM-1), L1-2^(vector) or L1-2^(ELAM-1) cells were applied to each well (1.5×10⁶ cells in 0.15 ml CM). Mouse lymphocytes isolated from mesenteric lymph nodes were also tested at 3×10⁶ cells in 0.15 ml. In some cases, cells were preincubated with monoclonal antibody MEL-14 (Gallatin et al., 1983, supra) at 150 μg/ml/10⁷ cells and washed prior to testing. After a 25 minute incubation at RT on a rotating shaker at 50 rpm, the tops of the wells were removed and the slides washed 3× in DMEM and then fixed by incubation in 1.5% glutaraldehyde (Kodak) in DMEM. Three to six 100× fields were counted for each data point and the average and standard error are reported. Data reported are from representative experiments which were performed 2-5 times with similar results.

Results

Lymphocytes bind to Sialyl Le^(x) and Sialyl Le^(a) containing neoglycoconjugates via LECAM-1. The determination that LECAM-1 cross-reacts with these ELAM-1 ligands (described in Example I) was performed by repeating this adherence assay with L1-2 cells transfected with human LECAM-1 cDNA (L1-2^(LECAM-1)) as well as with normal mouse lymphocytes which express high levels of mouse LECAM-1. Mouse lymphocytes bound Sialyl Le^(x) and Sialyl Le^(a), but not LNF I, Le^(a), Le^(x) or neoglycoconjugates containing 3′ sialyllactose, 6′ sialyllactose, or LSTa. Binding of mouse lymphocytes was blocked by anti-mouse LECAM-1 MAB MEL-14 (Gallatin, et al., 1983, supra) demonstrating that the adhesion observed is via LECAM-1. L1-2^(LECAM-1) cells all bind slightly better to Sialyl Le^(a) than Sialyl Le^(x) containing conjugates over a wide range of cell concentrations; both ELAM-1 and LECAM-1 appear to display similar relative binding abilities to these two simple carbohydrate ligands.

It is evident from the above results, that compositions can be employed which can be used to modulate the homing of leukocytes, particularly lympho-cytes, to sites of inflammation. These compounds can be readily prepared by conventional ways and can be effective for the treatment of a variety of diseases, both prophylactically and therapeutically.

All publications and patent applications mentioned in this specification are herein incorporated by reference to the same extent as if each individual publication or patent application was specifically and individually indicated to be incorporated by reference.

The invention now being fully described, it will be apparent to one of ordinary skill in the art that many changes and modifications can be made thereto without departing from the spirit or scope of the appended claims. 

What is claimed is:
 1. A method for decreasing the binding of leukocytes or platelets to endothelial cells, said method comprising: adding to a combination of cells comprising endothelial cells and leukocytes or platelets, wherein selectins or carbohydrate ligands thereof are expressed in an amount sufficient to promote the binding of leukocytes or platelets to endothelial cells, a glycoconjugate that recognizes a carbohydrate domain common to sialyl-Le^(x) and sialyl-Le^(a) and that is cross-reactive or competitive with sialyl-Le^(a) or the cutaneous lymphocyte associated antigen in binding to a selectin, with the proviso that said glycoconjugate is not a glycoconjugate of sialyl-Le^(x) or substituted sialyl-Le^(x).
 2. A method according to claim 1, wherein said glycoconjugate comprises sialic acid and fucopyranose bonded to a group comprising a conformationally constrained chain of at least 2 atoms.
 3. A method according to claim 2, wherein said group has a galactose, glucose or derivative thereof.
 4. A method according to claim 3, wherein said galactose is bonded as the β-anomer to a glucose, glucoseamine or N-acetyl glucoseamine.
 5. A method according to claim 4, wherein said glycoconjugate is a glycoconjugate sialyl-Le^(a) or derivative thereof. 